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Kinetics Overview

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Chemical Kinetics is the area of chemistry that deals with reaction rates. ... All you need is a stopwatch and a way to look at the reaction... Kinetics Overview ... – PowerPoint PPT presentation

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Title: Kinetics Overview


1
Kinetics Overview
  • Lets look at the big picture
  • Chemical Kinetics is the area of chemistry that
    deals with reaction rates.
  • Why do we study chemical kinetics?
  • -Determine how fast a reaction takes place/how
    long we need reaction to go to reach certain
    completion (or to reach equilibrium).
  • -Figure out the mechanism of the reaction
    (helpful when trying to make a reaction work
    better/shut it off).

2
Kinetics Overview
  • What do we mean by reaction rates?
  • What do we mean by the rate of a reaction?
  • How the concentration of a reactant or product
    changes over time.
  • Reaction rates are things that we can easily
    measure in the lab
  • All you need is a stopwatch and a way to look at
    the reaction

3
Kinetics Overview
  • What determines what the rate of a reaction will
    be?
  • Reaction Rates Depend on
  • 1. The nature of the reacting species
  • 2. The concentration of the reacting species
  • 3. The temperature of the reaction
  • 4. The presence or absence of a catalyst
  • We describe how a reaction is influenced by these
    different factors using a Rate Law.
  • There are two different types of rate laws
  • Differential how rate is dependent on
    concentration
  • Integrated how concentration depends on time
  • Differential Rate Laws are what we typically
    think of when we say rate law

4
Kinetics Overview
  • What determines what the rate of a reaction will
    be?
  • Reaction Rates Depend on
  • 1. The nature of the reacting species
  • 2. The concentration of the reacting species
  • 3. The temperature of the reaction
  • 4. The presence or absence of a catalyst
  • In a rate law one of the factors above is easily
    manipulated, which one is it?
  • Concentration of the reacting species
  • The other factors are rolled into the rate
    constant (k)which means that a rate constant is
    only good for a certain temperature (because of
    the Arrhenius equation).

5
Kinetics Overview
  • What does a rate law look like?
  • Differential rate laws have the general form
  • Rate k reactant speciesn
  • Where k the rate constant for that reaction at
    a given temperature
  • n the order of the reaction with respect to a
    given reactant species
  • Rate the rate of the reaction
  • There are many different ways we can describe the
    rate of a given reaction. We MUST be careful to
    clearly define the rate (it can have a big effect
    on the value we determine for the rate constant).

6
Kinetics Overview
  • Defining the rate we are looking at
  • A 2B ? 3C 4D
  • Rate of reaction - D A -1 D B 1 D
    C 1 D D kAmBn
  • Dt 2 Dt 3 Dt
    4 Dt
  • These are all valid ways to describe the rate of
    this reaction.
  • If we look at the coefficients of the balanced
    reaction, 4 molecules of D will be formed for
    each molecule of A that is consumed. The rate
    of formation of D over time would then be 4x
    that of the consumption of A. To make these
    two rates equal to each other we must multiply
    the rate of formation of D over time by (1/4).

7
Kinetics Overview
  • Example of relating k and rate of reaction
  • 2 NO2 (g) ? 2 NO (g) O2 (g)
  • If we studied this reaction in the lab would
    could define the rate law in the following
    fashion
  • Rate -1 D NO2 kNO2n
  • 2 Dt
  • Rate D O2 kNO2n
  • Dt
  • in this example 2 k k or k k/2
  • The value of k can vary for a reaction depending
    on our
  • definition of rate of the reaction.

8
Kinetics Overview
  • What do we do once weve proposed a rate law?
  • Once weve looked at a reaction and proposed a
    rate law we have to determine the order of the
    reaction. There are a couple of ways to do that
  • -Plotting data from integrated rate laws (see
    Buret Kinetics Power Point presentation from
    class)
  • -Isolation method with initial rates. You will
    be given a table of data with different
    concentrations of reactants and the initial rate
    of the reaction. (The book does a good job of
    demonstrating how to do these problems if you
    are still a bit shaky. See section 12.3 of
    Zumdahl)
  • Once we know the order of the reaction we can use
    the integrated rate law which allows us to relate
    concentration to time. Also opens the doors to
    calculating the half life of a reaction.

9
Kinetics Overview
  • Rate Laws for different orders
  • Zero Order
  • Differential Rate kAo k
  • Integrated A -kt Ao
  • First Order
  • Differential Rate kA1
  • Integrated lnA -kt lnAo
  • Second Order
  • Differential Rate kA2 or kAB if A
    B
  • Integrated 1/A kt 1/Ao
  • For each integrated rate law you should know what
    to plot for each order and what you would expect
    the graph to look like.

10
Kinetics Overview
  • Half lifes for different order reactions
    (assuming 1 reagent)
  • Another very useful application of integrated
    rate laws is the ability to determine the half
    life for a reaction (time where A Ao/2).
    This is very useful in looking at how long drugs
    will stay in a system, how long environmental
    waste will be present, and how long a given
    compound will be stable.
  • Zero Order
  • t1/2 Ao/2k (depends on Ao, half life gets
    shorter over time)
  • First Order
  • t1/2 ln 2/k (no Ao dependence, half life
    stays constant over time)
  • Second Order
  • t1/2 1/kAo (depends on Ao, half life gets
    longer over time)

11
Kinetics Overview
  • Pseudo 1st order kinetics
  • What do you do when you have more than 1 reagent
    and everything is too complicated???
  • To this point all rate laws have been of the
    form
  • rate kAn
  • However, this simple form will not work for a
    reaction like
  • A B ? C D (where A is not B
  • The rate law for this reaction would be
  • Rate kAmBn
  • This leads to a more complicated integrated rate
    law that doesnt fit the simple y mx b form.

12
Kinetics Overview
  • Pseudo 1st order kinetics
  • A B ? C D
  • To simplify this problem we use pseudo 1st order
    kinetics.
  • First, remember that the rate constant k, is a
    constant for this reaction.
  • If we use a large enough relative concentration
    of one of the reactants in the rate law (lets
    choose B), such that B Bo the
    concentration of B is essentially constant
    through the reaction.
  • We can then say the rate constant times the
    essentially constant B equals a new constant
    k.
  • k B k

13
Kinetics Overview
  • Pseudo 1st order kinetics
  • A B ? C D
  • If we substitute this new constant k into the
    original rate law
  • Rate kAmBn ? Rate kAm
  • The rate of the reaction is now essentially a
    first order process which we can solve using
    either an integrated rate law. But when we
    determine k for this pseudo 1st order process,
    we still must do some work to calculate k for the
    reaction.
  • Remember that k k B, so if we know the Bo
    of the reaction we can easily solve for k of the
    overall reaction.
  • This is a very useful tool to make really
    complicated problems simple.

14
Kinetics Overview
  • What does order tell us?
  • Other then telling us what integrated rate law to
    use to find k, what does the order of a
    reaction tell us?
  • Allows us to experimentally determine which step
    is rate determining. Why do we care about that?
  • Because of molecularity, we have a snap-shot of
    the number and kind of molecules that are
    colliding in the transition state of the rate
    determining step! We can see the reaction
    taking place,
  • The order of a reaction gives us a virtual
    snapshot into what the transition state of the
    reaction looks like!
  • Allows us to gain information about the
    mechanism of the reaction that we are studying.

15
Kinetics Overview
  • Reaction mechanisms
  • Reaction mechanisms are the written descriptions
    of the series of steps that take place in a
    chemical reaction.
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • Tells stoichiometry, but no info on reaction
    mechanism.
  • NO2 (g) NO2 (g) ? NO3 (g) NO (g) k1 (slow
    step)
  • NO3 (g) CO (g) ? NO2 CO2 (g) k2 (fast
    step)
  • Each of these steps is an elementary step, a
    reaction whose rate law can be written from its
    molecularity.
  • NO3 is produced in formed and consumed in the
    overall reaction, but isnt starting material or
    product intermediate.

16
Kinetics Overview
  • Reaction mechanisms
  • Reaction mechanisms must obey two requirements
  • 1. The sum of the overall elementary steps must
    give the overall balanced equation
  • 2. The mechanism must agree with experimentally
    determined rate law.
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • NO2 (g) NO2 (g) ? NO3 (g) NO (g) k1(slow
    step)
  • NO3 (g) CO (g) ? NO2 CO2 (g) k2 (fast
    step)
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • Given that the experimental rate k NO22. We
    know that the kinetics of this reaction will be
    based on RDS (slow step).

17
Kinetics Overview
  • Reaction mechanisms
  • Reaction mechanisms must obey two requirements
  • 1. The sum of the overall elementary steps must
    give the overall balanced equation
  • 2. The mechanism must agree with experimentally
    determined rate law.
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • NO2 (g) NO2 (g) ? NO3 (g) NO (g) k1(slow
    step)
  • NO3 (g) CO (g) ? NO2 CO2 (g) k2 (fast
    step)
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • Because each step in the mechanism is an
    elementary step, we can write the rate law from
    the initial step of the reaction.
  • Rate (step 1) k NO22 Rate (experimental)
    k NO22

18
Kinetics Overview
  • Reaction mechanisms
  • Reaction mechanisms must obey two requirements
  • 1. The sum of the overall elementary steps must
    give the overall balanced equation
  • 2. The mechanism must agree with experimentally
    determined rate law.
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • NO2 (g) NO2 (g) ? NO3 (g) NO (g) k1(slow
    step)
  • NO3 (g) CO (g) ? NO2 CO2 (g) k2 (fast
    step)
  • NO2 (g) CO (g) ? NO (g) CO2 (g)
  • This is a valid reaction mechanism and MAY be the
    how the reaction takes place.

19
Kinetics Overview
  • Collision Model/Arrhenius Equation
  • Why do reaction rates depend on
  • 1. The nature of the reacting species
  • 2. The concentration of the reacting species
  • 3. The temperature of the reaction
  • 4. The presence or absence of a catalyst
  • In order to answer these questions, scientists
    have proposed a collision model which says
  • Reactions can take place when we have collisions
    of molecules.
  • Sothe more concentrated the solution, the more
    collisions, and more reactions can take place
  • But why dont all collisions lead to a reaction?

20
Kinetics Overview
  • Collision Model/Arrhenius Equation
  • Why do reaction rates depend on
  • 1. The nature of the reacting species
  • 2. The concentration of the reacting species
  • 3. The temperature of the reaction
  • 4. The presence or absence of a catalyst
  • Each reaction has a certain energy
    barrier that must be reached for a reaction
    to take place (Ea)
  • Not enough energy? no reaction, wrong
    conformation?
  • no reaction. Higher Temp? More energy
    to get over barrier

21
Kinetics Overview
  • Collision Model/Arrhenius Equation
  • Why do reaction rates depend on
  • 1. The nature of the reacting species
  • 2. The concentration of the reacting species
  • 3. The temperature of the reaction
  • 4. The presence or absence of a catalyst
  • The Collision Model can be summed up by one of
    the greatest equations in all of the land
    Arrhenius equation
  • k A e -Ea/RT
  • Where A is the frequency factor (which takes the
    nature of the reacting species into account) and
    Ea is the activation energy.
  • This equation also shows why a rate constant is
    only valid for 1 temp.

22
Kinetics Overview
  • Catalysts
  • Why do reaction rates depend on?
  • 1. The nature of the reacting species
  • 2. The concentration of the reacting species
  • 3. The temperature of the reaction
  • 4. The presence or absence of a catalyst
  • The last thing that will effect the rate of a
    reaction is a catalyst.
  • Catalysts speed up the rate of reaction without
    being consumed (it will get consumed, it just
    gets regenerated later)
  • There are two types of catalysts
  • -Heterogeneous different phase
  • -Homogeneous same phase (Enzymes are the
    ultimate cat.)
  • Both types work using the same principle
  • Lower the activation energy of a reaction (giving
    a lower energy pathway for the reaction to take
    place)

23
Kinetics Overview
  • Collision Model/Arrhenius Equation
  • The easiest way to see how a catalyst works is to
    look at an energy diagram
  • The catalyst offers an alternative pathway which
    has a lower EaArrhenius equation tells us that
    this will have a faster rate

24
Kinetics Overview
  • Conclusion
  • When I think about kinetics, it helps me to break
    it into a series of different steps that we can
    use to answer questions.
  • -What is the rate Im looking at? How have I
    defined the rate law?
  • -What is the order of the reaction? What does
    that tell me?
  • -What is the rate constant in this reaction?
    That will let me determine the concentration of
    reactants at different times (which is really
    useful).
  • -What mechanism does this kinetic data support?
  • -How can I improve/change the reaction rate?
    Increase concentrations? Increase temperature?
    Add a catalyst?
  • -Are there other questions being asked?
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